Drastic Gas Sensing Selectivity in 2-Dimensional MoS₂ Nanoflakes by Noble Metal Decoration

Abstract: Noble metal nanoparticle decoration is a representative strategy to enhance selectivity for fabricating chemical sensor arrays based on the 2-dimensional (2D) semiconductor material, represented by molybdenum disulfide (MoS2). However, the mechanism of selectivity tuning by noble metal decoration on 2D materials has not been fully elucidated. Here, we successfully decorated noble metal nanoparticles on MoS2 flakes by the solution process without using reducing agents. The MoS2 flakes showed drastic selectivity… Show more

“…5a). 76 The pristine MoS 2 exhibited a high response and selectivity to NH 3 ( R a R g −1 − 1 = 4.7, S NH 3 / S I >8.0 to 50 ppm at 150 °C). It is attributable to the strong binding energy of the MoS 2 edge site to NH 3 , which was confirmed by density functional theory (DFT) calculations.…”

Food quality assessment using chemoresistive gas sensors: achievements and future perspectives

“…5a). 76 The pristine MoS 2 exhibited a high response and selectivity to NH 3 ( R a R g −1 − 1 = 4.7, S NH 3 / S I >8.0 to 50 ppm at 150 °C). It is attributable to the strong binding energy of the MoS 2 edge site to NH 3 , which was confirmed by density functional theory (DFT) calculations.…”

Food quality assessment using chemoresistive gas sensors: achievements and future perspectives

“…Thus, such a high selectivity towards NO 2 among other gases is a huge advantage of rGO as a sensing material. The selectivity of a 2D nanoparticle-based sensor can be tuned from being favor to one gas type to another through surface decoration of the 2D nanoparticle with metal or noble metal [62,63]. This tunable properties of the gas sensor were achieved through different adsorption strengths between the metal-doped 2D nanoparticle and the target gas type.…”

Progress and Insights on Graphene and MXene‐based Emerging 2‐Dimensional Conductive Nanomaterials for Fabrication of Flexible Gas Sensors

“…Recently, two-dimensional (2D) materials have been actively deployed to fabricate various electronic and optoelectronic devices. [33][34][35][36][37][38][39][40][41][42] Their high charge carrier mobility, [43][44][45] band gap tunability, 46 high light absorption coefficient, 40,45 ease of heterojunction formation, 47 and high surface-to-volume ratios 48 make them promising candidates for realizing RS memory and other neuromorphic circuit elements. 10,12,49 Furthermore, van der Waals (vdW) heterojunctions synthesized by stacking two or more 2D layered materials (2DLMs) not only retain the properties of the individual 2D materials, but also exhibit more intriguing properties than the respective counterparts.…”

Brain-inspired computing: can 2D materials bridge the gap between biological and artificial neural networks?